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International Journal of Engineering Trends and Technology (IJETT) – Volume 4 Issue 5- May 2013
Low Power Full Adder With Reduced Transistor Count
M.Geetha Priya 1
1
2
Assistant Professor, Amrita Vishwa Vidyapeetham, Coimbatore
Associate Professor, Government College of Technology, Coimbatore
Abstract— Basic building blocks of most of the arithmetic and
logic circuits are formed by XOR logic gate. This paper
proposes a new 3T-XOR gate with significant area and power
savings. In most of the digital systems adder lies in the critical
path that increases the overall computational delay of the
system. A new eight transistors one bit full adder based on
3T-XOR gate is presented. Simulations results utilizing
standard 90nm CMOS technology illustrate a significant
improvement in terms of number of transistors, chip area and
propagation delay.
Keywords— Full adder, CMOS, PDP, Pass transistor, XOR,
low power.
I. INTRODUCTION
The growing demand for portable devices
is driving the chip designers to rely on scaling
down of device sizes with increased computation
performance and longer battery life. The
increasing chip density and complexity has led to
more power consumption. This directly affects
the battery operated portable devices and requires
expensive cooling and packaging technologies.
There are three types of power
consumption in VLSI circuits namely short
circuit power, static power and dynamic power.
The short circuit power dissipation is due to the
short circuit current generated when both NMOS
and PMOS transistors are simultaneously active
for a small duration. The static power dissipation
varies with process technology. The dominant
dynamic power due to charging and discharging
of load capacitance is given by the following
equation (1),
Dynamic Power = α (VDD) 2 f CL
ISSN: 2231-5381
K.Baskaran 2
where α is the switching activity, VDD is the
supply voltage, f is the switching frequency CL
is the load capacitance. Lower the voltage is, the
smaller the power consumption. However, using
a lower VDD increases the delay. The alternate
way of decreasing the power is by reducing the
number of switching transistors.
Around 30% of the total power is
consumed by the data path. Adders are an
extensively used component in data path and
therefore careful design and analysis is required.
The overall system performance can be increased
significantly by enhancing the performance of the
full adders. XOR logic gates play an important
role in building up of most of the data path units,
specifically adders, multipliers, phase detectors,
comparators, parity checkers and compressors.
The early designs of XOR gate was based on
either eight transistors or six transistors [1] that
are conventionally used in most designs. This
paper proposes a new design technique for a 3TXOR gate [2] circuit based on static CMOS
inverter logic and Pass transistor logic (PTL).
The rest of the paper is organized as follows, in
Section 2, a review of full adders in previous
works is presented. In Section 3, the proposed
work on XOR gate and full adder circuit is
presented, which is followed by the simulation
results and conclusions in Sections 4 and 5,
respectively.
--- (1)
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International Journal of Engineering Trends and Technology (IJETT) – Volume 4 Issue 5- May 2013
II. REVIEW OF FULL ADDER TOPOLOGIES
Most of the Full adder structures make
use of XOR and XNOR logic gates.
Conventional CMOS [3] full adder with 28
transistors is a high power and robust full adder.
This design is based on complementary pull up
and pull down topologies. It has high noise
margin and reliability. The CMOS full adder
suffers from large power consumption and high
delay. New 14T full adder [4] based on
simultaneous XOR-XNOR signals is an
improvement from 14T full adder. However, it
suffers from high delay. The feedback transistors
need special attention, when sizing is done that
increases the layout complexity. The TGA full
adder [5] using 20 transistors is based on CMOS
transmission gates and CMOS inverters. It
provides full output voltage swing. In TFA [6],
the design was improved with 16 transistors and
maintains full output voltage swing operation.
Complementary pass transistor logic (CPL) full
adder [3] provides high speed and full swing
operation. The presence of many internal nodes
and inverters results in large power dissipation.
The Hybrid pass logic (HPSC) full adders [7]
with 22 transistors have poor PDP. For low
supply voltages, the PDP rises drastically making
them unsuitable for low-voltage operation. The
hybrid CMOS style full adder [8] with 24
transistors has better noise immunity and
performs well with low voltages. The proposed
8T full adder shows better results in terms of
power, delay and PDP. It occupies less area in
terms of transistor counts, more suitable for
supply voltage scaling and under different load
conditions.
III. PROPOSED 3T-XOR GATE AND FULL ADDER
is the complement of input X. When the input Y
is at logic zero, the CMOS inverter output is at
high impedance. However, the PMOS pass
transistor M3 is turned ON and the output gets
the same logic value as input X. The operation of
the whole circuit could be given as a 2 input
XOR gate as given in Table-1.
Exact output logic levels are obtained for
all the input combinations without any voltage
degradation. However, when X=0 and Y=0,
voltage degradation due to threshold drop occurs
across the PMOS pass transistor M3 while
passing the output logic zero and consequently
the output is degraded with respect to the input.
The voltage degradation due to threshold drop
can be considerably minimized by increasing the
W/L ratio of transistor M3 [9]. The equation (2)
relates the threshold voltage of a MOS transistor
to its channel length and width.
(V + ϕ ) V = V +g V + ϕ -α1
αv
V +αw
(V
+ϕ )
---(2)
where V is the zero bias threshold voltage, g is
bulk threshold coefficient, ϕ is ϕ , where ϕ is
the Fermi potential, tOX is the thickness of the
oxide layer and α1, α v and α w are process
dependent parameters. From equation (2) it is
obvious that by increasing the width W of
transistor M3, keeping the length constant it is
possible to reduce the voltage degradation due to
the threshold voltage. Typical values of transistor
widths
Wp =3.0µm for PMOS M1, Wn
=1.5µm for NMOS M2, and Wp =5.0µm for
PMOS M3 have been taken. The length for all
the transistors have been taken constantly as L=
0.09 µm (90 nm).
The proposed new design of XOR logic
gate using three transistors is shown in Figure-1.
The design is based on modified CMOS inverter
and PMOS pass transistor logic. When the input
Y is at logic one, the inverter on the left functions
as a normal CMOS inverter. Therefore the output
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International Journal of Engineering Trends and Technology (IJETT) – Volume 4 Issue 5- May 2013
TABLE 1
A. Full adder module
LOGIC TABLE OF 3T XOR GATE
Input-A
0
0
1
1
Input-B
0
1
0
1
Output = X’Y+XY’
X/0
X’/1
X/ 1
X’/0
Fig 1. 3-Transistor based XOR
The full adder operation can be given as
follows: Given the three 1-bit inputs A, B, and C,
it is desired to calculate the two 1-bit outputs
Sum and Carry, where Sum=  and
Cout = 
Full adder circuit can be implemented
with different combinations of XOR, XNOR and
2x1 multiplexer blocks. The goal of this paper is
to design a high performance and low power full
adder module with 8T. Compared to the various
logic structures, the proposed Full Adders
embodies only 8 transistors and the number of
interconnections between them is highly reduced.
Having each transistor a lower interconnection
capacitance, the power consumption is reduced to
a great extent. The proposed 8T full adder is
based on XOR/XOR logic constructed using two
3T XOR cells and one multiplexer as shown in
block diagram of Figure-2(a). Two XOR gates
generate the sum and 2T multiplexer block
generate Cout. The 1-bit full adder with eight
transistors has been implemented and shown in
Figure-2(b).The typical values of width (Wn &
WP) 1.5µm & 3µm have been taken for NMOS
and PMOS transistors respectively in the
multiplexer block with gate length of 0.09µm.
IV. RESULTS
(a)
(b)
Fig 2. Full adder using two XOR gates and multiplexer (a) Block diagram
(b) Circuit diagram
ISSN: 2231-5381
In order to compare the results of the
proposed full adder circuits with the existing full
adders, a wide range of experiments was carried
out. Schematics are designed for all the circuits
using Custom Designer in Synopsys for TSMC
0.18µm technology. Netlists obtained from the
schematics are used to simulate and test
performance. The original netlists are modified
according to the process technology targeted
using the Berkeley Predictive Technology Model
(BPTM) 90nm process. The modified netlists are
simulated using Synopsys HSPICE for power and
delay estimations. The worst case power and
delay measurements are made in all the cases.
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International Journal of Engineering Trends and Technology (IJETT) – Volume 4 Issue 5- May 2013
Figure-3 (a) & (b) shows input and output
waveform results for XOR cell and 8 transistor
full adder respectively. The XOR and full adder
circuits provide full swing output voltage with
respect to sizing of transistors for threshold
voltage degradation. Short circuit currents are
also quite low in the XOR circuit as direct path
from supply to ground is eliminated.
Full adder circuits discussed in [3] to [8]
have been simulated and comparisons have been
presented in Table-2. During the HSPICE
simulation, for all the existing adders transistor
width was taken as Wn = 1.5µm & Wp = 3µm
with input voltage = 1V and transistor length
L=0.09 µm. Graph drawn in Figure-4 shows
comparison of power and delay of proposed
adder circuit with other adder circuits. It has been
shown that proposed adder circuit show less
power consumption and delay than previously
reported adders. Proposed circuits also show
superiority in terms of transistor count with
earlier reported circuits. Proposed full adder has
less internal capacitance as number of transistors
is reduced and gives reduced power
consumption.
(b)
Fig 3. Input-Output waveforms with VDD=1V (a) proposed XOR circuit
(b) 8T Full adder
TABLE II
SIMULATION RESULTS FOR THE PROPOSED FULL ADDER CIRCUITS IN 90NM
PROCESS TECHNOLOGY AT 50MHZ FREQUENCY
Adder
No. Of
Transistors
Power(nW)
Delay(ps)
PDP( E21 J)
CMOS
CPL
TGA
TFA
HPSC
Hybrid
CMOS
14T
Proposed
8T
28
32
20
16
22
24
54.72
76.82
42.99
41.02
38.83
34.68
375.2
462.8
282.5
297.1
539.8
372.9
20530
35552
12144
12187
20960
12932
14
8
45.29
5.87
427.6
288.4
19366
1692
(a)
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(c)
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International Journal of Engineering Trends and Technology (IJETT) – Volume 4 Issue 5- May 2013
[6]
[7]
[8]
[9]
N. Zhuang and H. Wu, “A new design of the CMOS full adder,”
IEEE J. Solid-State Circuits, vol. 27, no. 5, pp. 840–844, May
1992.
M. Zhang, J. Gu, and C. H. Chang, “A novel hybrid pass logic
with static CMOS output drive full-adder cell,” in Proc. IEEE
Int. Symp.Circuits Syst., May 2003, pp. 317–320.
S. Goel, A. Kumar, and M. Bayoumi, “Design of robust,
energy-efficient full adders for deep-submicrometer design
using hybrid-CMOS logic style,” IEEE Trans. Very Large
Scale Integr. (VLSI) Syst., vol. 14, no. 12, pp. 1309–1320, Dec.
2006.
Y.Tsividis, Mixed Analog-Digital VLSI devices and
Technology, Singapore: McGraw Hill, 1996.
(d)
Fig 4. Comparison of (c) Power and (d) Delay for various Full adders
V. CONCLUSION
In this paper, we have presented a
systematic approach to construct full adder using
only eight transistors based on new XOR cell.
The proposed approach resulted in low power
consumption and high speed compared to the
existing full adder architectures. According to
HSPICE simulation in 90 nm CMOS process
technology at room temperature, and under given
conditions, the proposed full adder shows an
improvement
of
89%
average
power
consumption over conventional CMOS adder. In
addition, the delay and power-delay product
results depict impressive improvement over
conventional CMOS adder.
REFERENCES
[1]
[2]
[3]
[4]
[5]
Y. Leblebici, S.M. Kang, CMOS Digital Digital Integrated
Circuits, Singapore: Mc Graw Hill, 2nd edition, 1999, Ch. 7.
Shubhajit Roy Chowdhury, Aritra Banerjee, Aniruddha Roy,
Hiranmay Saha, “A high Speed 8 Transistor Full Adder Design
using Novel 3 Transistor XOR Gates,” International Journal of
Electrical and Computer Engineering, vol 3 ,pp. 784-790, 2008.
R. Zimmermann and W. Fichtner, “Low-power logic styles:
CMOS versus pass-transistor logic,” IEEE J. Solid-State
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